Door securement mechanism for waterproof encasement

ABSTRACT

A door securement system for a protective case for housing a mobile device is provided. The protective case comprises a top shell that covers a top surface of a device and a bottom shell that cradles the back of the device. Where upper and lower backing elements are used that meet at a parting line along the outer (exterior) surface of the bottom shell, a locking mechanism may be used to pull the backing elements together and hold them in place. A multi-hinged door is positioned along a portion of the protective case to allow access to ports of the mobile device. The door has open, shut and sealed configurations.

CROSS-REFERENCE TO RELATED APPLICATIONS

This non-provisional patent application is a continuation-in-part of U.S. Non-Provisional patent application Ser. No. 14/340,305, filed Jul. 24, 2014, which claims priority to U.S. Provisional Patent App. No. 61/872,074 filed on Aug. 30, 2013 and 61/893,672 filed on Oct. 21, 2013. The entirety of U.S. Non-Provisional patent application Ser. No. 14/340,305, U.S. Provisional Patent App. No. 61/872,074, and U.S. Provisional Patent App. No. 61/893,672 are incorporated by reference herein.

TECHNICAL FIELD

Generally, this application relates to cases for portable electronic devices, and more particularly, to cases that may be used to protect a portable electronic device (or, more simply, a “device”). As used herein, the term “hand-held electronic device” may include any type of wireless communication devices, such as, e.g., mobile telephone, tablet, portable computer, gaming device, media player, smart phone, personal organizer, and the like. Though the primary embodiment discussed herein relates to a case for a mobile phone, it will be understood that the principles of the invention could be adapted to other geometries for use with other hand-held electronic devices.

BACKGROUND

As mobile communication devices, PDAs, tablets and other consumer electronic devices have become commonplace, so have the various casings used to protect those devices. Simpler, inexpensive cases involve merely a bottom shell in which the phone is seated that provides side, top and bottom walls to wrap around the device, and a raised rim around its operative interface. Others seek to cover over the operative interface with a film or membrane to provide additional protection, or to attempt to seal the device and make the casing water-proof. Waterproof or water-resistant cases are typically of a clamshell variety, wherein top and bottom shells are fitted together around the mobile device. For clamshell-style casings, whether or not they involve a membrane, various mechanisms have been used to secure the two shells together, ranging from clamps to hinges. Simply pressing the two shells together and using an over-lapping edge or press-fit is perhaps the simplest and most well-known means. However, such an over-lapping interface may wear down over time with repeated use and fail to provide a secure connection. Alternatively, more secure clamshell connections using extraneous hardware (clamps, hinges, etc.) are less user-friendly and more expensive.

SUMMARY OF THE INVENTION

The present invention provides a clam-shell style case for a handheld mobile device that features a user-friendly concept to secure the shells without extraneous hardware, yet that provides a robust connection and additional protection from impacts. The top component may or may not have a membrane over the operative interface of the device. The shells are secured together with upper and lower backing elements that are slid together along a protrusion formed by one or both of the clam shells. The backing elements provide additional impact resistance and protection to the device, while serving to hold the upper and lower shells securely together.

In some instances, the invention discloses a case for a mobile device comprising a rigid top shell forming a perimeter around a front face of the device; a bottom shell forming a cradle for a rear face of the device; and a backing element that, when the rigid top shell and the bottom shell are placed around the device, slides along first and second outward protrusions formed by at least the rigid top shell, the first protrusion extending along at least a portion of a first side edge of the device and the second protrusion extending along at least a portion of a second side edge of the device; wherein the backing element extends under the bottom shell and around the first and second protrusions, thereby securing the top shell and bottom shell together around the device.

In other instances, the invention discloses a case for a generally rectangular mobile device having a front surface with an interactive control panel thereon, a back surface, a top surface, a bottom surface and first and second side surfaces, the case comprising: a top shell forming a perimeter around the interactive control panel of the mobile device and comprising a first side wall extending toward the back surface of the device along the first side surface of the device, and a second side wall extending toward the back surface of the device along the second side surface of the device, each of the first and second side walls comprising a downward extension and an outward protrusion, each outward protrusion forming a rail that extends along at least a portion of its respective side wall; a bottom shell forming a cradle for the bottom surface of the mobile device and comprising a first upstanding perimeter wall along at least a portion of the first side surface of the mobile device and a second upstanding perimeter wall along at least a portion of the second side surface of the mobile device, each of the first and second upstanding perimeter walls forming a trench for receiving at least a portion of one of the downward extensions; and a backing element at least partially encompassing the bottom shell and having backing element side walls that extend substantially parallel to the first and second side surfaces of the mobile device, beyond the first and second perimeter walls of the bottom shell, and around the rails formed by the outward protrusions of the top shell in order to hold the top shell and bottom shell together around the mobile device.

In yet other instances, the invention discloses a waterproof, impact-resistant case for a handheld computing device, the device being of substantially rectangular proportions and having a front surface, a rear surface, a top edge, a bottom edge, and left and right side edges, the case comprising: a rigid top shell for placement over the front surface of the device, the top shell comprising side walls, each side wall extending from the front surface of the device, along the left or right side edge of the device to a side wall terminus near the rear surface of the device, each side wall comprising an outward protrusion extending away from the left and right side edges of the device and forming a top shelf along and parallel to the left and right side edges; a bottom shell having an interior surface for placement against the rear surface of the device and an exterior surface facing away from the device, the bottom shell forming left and right trenches along and parallel to the left and right side edges of the device, the trenches each configured to receive a side wall terminus of the top shell; an upper backing element extending across a portion of the exterior surface of the bottom shell and along a portion of the side walls of the top shell, the upper backing element comprising an overhang for sliding along the top shelf formed by the outer protrusions of the top shell; and a lower backing element extending across a portion of the exterior surface of the bottom shell and along a portion of the side walls of the top shell, the lower backing element comprising an overhang for sliding along the top shelf formed by the outer protrusions of the top shell; wherein the upper backing element and the lower backing element are configured to slide together along the top shelf such that they join together along a parting line between the top edge and the bottom edge of the device.

In yet other instances, the invention discloses a waterproof, impact-resistant case for a handheld computing device, the case having a door securement system comprising an encasement body providing a cavity for housing an electronic device, the cavity including an opening at one end configured to enable acceptance of a temporary wired electrical connection, a lifting tab rotatably coupled to the encasement body via a second hinge pin, the lifting tab configured to transition from a locked configuration to an open configuration, and a door rotatably coupled to the lifting tab via a first hinge pin, the door configured to seal the opening from water egress in the locked configuration and enable access to the opening in the open configuration.

In yet other instances, the invention discloses a waterproof, impact-resistant case for a handheld computing device, the case comprising a door securement system comprising an encasement body providing a cavity for housing an electronic device, the cavity having an opening at one end to allow for temporary wired electrical connection to a emote input or output, a door for sealing the opening when the wired electrical connection is absent, a rocker assembly for rotatably connecting the door to the encasement body, the rocking assembly comprising, a series of extensions, each extension having a proximate through hole and a distal through hole, a first hinge pin extending along a first axis and passing through each proximate through hole and through an encasement body hinge, and a second hinge pin extending along a second axis to pass through each distal through hole and through a door hinge.

In yet other instances, the invention discloses a waterproof, impact-resistant case for a handheld computing device, the case comprising a door securement system for an encasement comprising an encasement body providing a cavity for housing an electronic device, the cavity having an opening at one end, and the encasement body forming a first clasping lip adjacent to a first side of the opening, a lifting tab having a first hinge pin rotatably connecting the lifting tab to the encasement body adjacent to a second side of the opening, and a sealing door configured to span the opening, the sealing door having a first perimeter side rotatably connected to the lifting tab by a second hinge pin, and a second perimeter side comprising a second clasping lip configured to overlap the first clasping lip to connect the sealing door to the encasement body.

The above system may have a first configuration in which the first clasping lip is separated from the second clasping lip, and the second perimeter side of the door is rotated away from the first side of the opening to allow wired access to a charging port on an electronic device housed within the cavity of the encasement body, a second configuration in which the first clasping lip overlaps the second clasping lip, and the lifting tab is rotated away from the encasement body such that the first perimeter side of the door is separated from the second side of the opening, and a third configuration in which the first clasping lip overlaps the second clasping lip and the lifting tab is rotated substantially flush with the encasement body such that the first perimeter side of the door is sealed against the second side of the opening.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention can be better understood with reference to the following drawings. The components in the drawings are not necessarily to scale, emphasis instead being placed upon clearly illustrating the principles of the present invention. In the drawings, like reference numerals designate corresponding parts throughout the several views.

FIG. 1 is an exploded view of case components forming around a mobile device in accordance with a first exemplary embodiment.

FIG. 1A is an exploded view of case components forming around a mobile device in accordance with a second exemplary embodiment.

FIG. 1B is a front isometric view of the case of FIG. 1A when fully assembled, but with the mobile device not included.

FIG. 2 is a frontal view of the case of FIG. 1 when fully assembled around a mobile device.

FIG. 3 is a section view of a side edge of the case of FIG. 1 taken through section 3 as shown in FIG. 2

FIG. 4 is a perspective view of the inner side of the top shell of the case of FIG. 1.

FIG. 4A is a perspective view of the inner side of the top shell of the case of FIG. 1A.

FIG. 4B is an exploded view of the elements of the top shell shown in FIG. 4A.

FIG. 5 is a perspective view of the inner side of the bottom shell of the case of FIG. 1, with hidden lines showing the twist lock assembly on its bottom side.

FIG. 5A is a perspective view of the outer side of the bottom shell of the case of FIG. 1A.

FIG. 5B is an exploded view of the elements of the bottom shell shown in FIG. 5A.

FIG. 6 is a perspective view of the outer (back) side of the case of FIG. 1 as it is being assembled about a mobile device.

FIG. 6A is a perspective view like that of FIG. 6, but with the case fully assembled about a mobile device, and with an optional carrying strap installed.

FIG. 6B is a perspective view of the inside of the upper backing element of the case of FIG. 1, illustrating a headphone jack connection.

FIG. 7 is a rear view showing the back side of the case of FIG. 1A, fully assembled about a mobile device.

FIG. 7A is front isometric view of the upper and lower backing elements of the case of FIG. 1A locked together, with the connection door opened.

FIG. 7B is an exploded view of the components of the backing elements shown in FIG. 7A.

FIG. 8 is a close-up perspective view of the twist lock assembly of the bottom shell of the case of FIG. 1, according to certain embodiments.

FIG. 9 is a corresponding section of the lower backing element of the case of FIG. 1 that mates with a portion of the twist lock assembly.

FIG. 10 is an exploded view of top and bottom shells of a case according to a third exemplary embodiment.

FIG. 11 is a section view taken through a side of a fully assembled case having no membrane in accordance with the embodiment shown in FIG. 10.

FIG. 11A is a section view taken through a side of a fully assembled case having a membrane in accordance with the embodiment shown in FIG. 10.

FIG. 11B is a section view taken through the side of the case shown in FIG. 7.

FIG. 12 is a perspective view of the underside of the top shell of the case of FIG. 10.

FIG. 13 is a perspective view of the upper and lower backing elements of the case of FIG. 10.

FIG. 14 is an exploded view of the case of FIG. 10, showing backing elements being installed over the top and bottom shells, in turn, assembled around a mobile device.

FIG. 15 is an exploded view of case components forming around a mobile device in accordance with a fourth exemplary embodiment.

FIG. 16 is a side view of the case from FIG. 15 when fully assembled around a mobile device.

FIG. 17 is a section view of a side edge of the case from FIG. 15 taken through section 17-17 as shown in FIG. 16.

FIG. 18 is an exploded view of components of a lower backing element shown in FIG. 15.

FIG. 19 illustrates a section of the lower backing element of FIG. 18 in a first condition.

FIG. 19A illustrates a section of the lower backing element of FIG. 18 in a second condition.

FIG. 19B illustrates a section of the lower backing element of FIG. 18 in a third condition.

FIG. 20 is a bottom view of the case from FIG. 15 showing components of a doorclasp assembly.

FIG. 21 illustrates a section of the case from FIG. 15 taken through section 21-21 as shown in FIG. 20.

DETAILED DESCRIPTION

The description that follows describes, illustrates and exemplifies one or more particular embodiments of the present invention in accordance with its principles. This description is not provided to limit the invention to the embodiments described herein, but rather to explain and teach the principles of the invention in such a way to enable one of ordinary skill in the art to understand these principles and, with that understanding, be able to apply them to practice not only the embodiments described herein, but also other embodiments that may come to mind in accordance with these principles. The scope of the present invention is intended to cover all such embodiments that may fall within the scope of the appended claims, either literally or under the doctrine of equivalents.

FIG. 1 shows an exploded view of a case 100 for a mobile device, such as an iPad® tablet. It will be understood that the components of the case, and the dimensions and shape, could be modified to fit other types of mobile devices without departing from the novelty of the invention. The case of FIG. 1 is comprised of four principle parts: a top shell 110, a bottom shell 120, and upper and lower backing elements 130, 140. These are shown in a fully-assembled condition around a mobile device 105 in FIG. 2, wherein the bottom shell 120 is fully enclosed and not in view. Generally, the top shell 110 and bottom shell 120 come together around the perimeter of the mobile device 105 to partially enclose it. Each of the top shell 110 and bottom shell 120 provide an outward protrusion 112, 122, said outward protrusions aligning with one another as shown in the cross section of FIG. 2. The upper and lower backing elements 130 and 140 each have a channel 132, 142 on either side sized to cooperate with the two outward protrusions 112, 122. The backing elements 130, 140 may be slid over the protrusions 112, 122 (with the protrusions in the channels 132, 142) until they meet. The channels 132, 142 serve to hold the top shell 110 and bottom shell 120 together around the mobile device 105. The two backing elements 130, 140 are then drawn together by turning a twist lock assembly 180 along the boundary where the backing elements come together. An optional harness strap 190 may be inserted into the backing elements 130, 140 so as to provide a grip for the device 105 when in the case 100.

The top shell 110 may be formed of a generally rigid plastic, such as polycarbonate. It is generally rectangular in shape, having top and bottom outer edges 114, 115 and opposing side outer edges 116, 117 that extend beyond the outer perimeter of the device to be enclosed. The top shell also has opposing inner edges 118 and top and bottom inner edges 119 that fit snugly against the device 105 along the edges of its screen. In some embodiments, the top shell 110 may contain a translucent membrane that covers the device screen (not shown). The top shell 110 provides a flexible overmold 111 aligned with the power control 106 for the device 105 so that the control may be operated while the device is in the case. It will be understood that this overmold can be moved or resized to fit with the operative controls of other devices. The top shell 110 also provides a perimeter seal 155 (see FIG. 3) along its inside perimeter for use in sealing against the device screen. The top shell 110 has a clasp retainer 157 along its bottom outer edge 115 for retaining a clasp that seals the power port (lightening port) of the device 105 (not shown) when not in use.

A cross section of the top shell 110 is shown in FIG. 3. As shown, a perimeter seal 155 comes to rest on the surface of the device itself, near the inner perimeter of the inside edge 118. The shell 110 is raised toward its center to provide a protective rim 113 around the enclosed device 105, and then falls away toward its outer perimeter 117. Between its inner and outer perimeters 118, 117, the shell 110 comprises a downward extension 109 to partially form sidewalls for enclosing the device 105. Fixed to the bottom of the extension is a joining seal 153, which runs the perimeter of the shell 110. This seal 153 is made to fit into a pocket 124 formed in the bottom shell 120, as described below. The extension also comprises an outward protrusion 112 that is used to help secure the top shell 110 to the bottom shell 120, by way of the backing elements 130, 140.

The bottom shell 120 forms an open-faced housing for the device 105, and is designed to conform to the outer dimensions of the device 105. In the disclosed embodiment, the bottom shell 120 is a generally flat, rectangular object with slightly upstanding walls along its two sides 127, top 128 and bottom 129. A camera hole 123 is aligned with a camera lens in the device 105, and other such openings may be provided so as to allow interplay and function of other utilities of the device. These openings may be sealed with translucent windows in some embodiments. As shown in the cross-section of FIG. 3, the upstanding walls 125 of the bottom shell 120 cooperate with the downward shell extensions 109 to form the sidewalls of the device case 100. The upstanding walls 125 comprise a pocket 124 that accommodates a portion of the downward extension 109 of the top shell 110, and the joining seal 153 attached thereto. Ideally, the seal 153 will form a slight interference fit within the pocket 124 to help retain the top shell 110 and bottom shell 120 together prior to the backing elements 130, 140 being installed. However, note that there are no overlapping surfaces, locking mechanisms, ribs, or clasps that hold the two components 110, 120 together in FIG. 3. Instead, the bottom shell's upstanding walls provide a second outward protrusion 122 that cooperates with and aligns with the first outward protrusion 112 of the top shell 110, which are collectively held in place by the backing elements, 130, 140, as explained below.

The upper and lower backing elements 130, 140, essentially form a second layer bottom shell for the device 105, but with taller upstanding walls that extend above the sides 127, top 128 and bottom 129 walls of the bottom shell 120. The upper backing element 130 provides a generally flat inner surface, with an upstanding top wall 138 and upstanding side walls 134. There is no wall opposite the top wall. Instead, the flat inner surface simply drops off along an edge. In the disclosed embodiment, the edge is parallel to the top wall 138, but that is not required. In the center of the edge is a semi-circular punchout 139, which is used to help draw the backing elements 130 and 140 together, as explained below. Also along the flat surface is a hole 137 to align with the camera hole 123 in the bottom shell 120. In the illustrated embodiment, there is also Velcro, or some other retaining material 135 disposed at a central area near a slit 136. The slit 136 is better illustrated in FIG. 3, where the outside of the flat surface is illustrated. The purpose of the slit 136 and retaining material 135 is discussed below.

As shown best in the cross-section of FIG. 3, each side wall 134 provides a channel 132 that is used to secure the top shell protrusion 112 to the bottom shell protrusion 122 (thereby securing the top shell 112 to the bottom shell 122. In operation, a user places the top shell 112 and bottom shell 122 around the device 105, and then aligns the channel 132 of the upper backing element with the joined protrusions 112, 122, and slides the protrusions into the channel 132 until the top wall 128 of the bottom shell 120 fits up against the top wall 138 of the upper backing element 130. This same operation is also conducted with the lower backing element 140.

The features of the lower backing element 140 mirror that of the upper backing element 130 except, in the illustrated embodiment, the camera hole is on the upper portion, and the power port is on the lower portion. Thus, as shown, the lightning port clasp 158 is hinged to the lower backing element 140 along its bottom wall. It will be understood that these features dependent on the location of controls and other inputs/outputs of the device to be encased will drive the location of these access features in the case 100. Otherwise, the lower backing element 140 has side walls 144 that feature a channel 142 designed to align with channel 132 in the upper backing element. Channel 142 (not shown in FIG. 3 because of where the section is taken), thus, also slides along the protrusions 112, 122 to help hold the top shell 110 and the bottom shell 120 together. Mirroring the upper backing element 130, the lower backing element 140 has a bottom wall 148, but no top wall. Instead, its flat inner surface that extends between side walls 144 drops off along an edge parallel to the bottom wall 148. This edge has a punchout 149 that mates with punchout 139 as shown in FIGS. 3 and 4 where the backing elements join together. The lower backing element 140 also features retaining material 145 and a slit 146.

As shown in FIG. 3, each of the backing elements 130, 140 may have a pliable overmold (shown as 133, corresponding to the upper backing element 130 in FIG. 1) along the outside of their side walls 134, 144. This overmold serves to allow pressure-based access to underlying device 105 controls, and also provides additional impact absorption in the event of drops.

Along the top wall 138 is a built-in phone jack extension assembly 165 (see FIG. 6B). A first end of the extension extends inward/downward from the top wall 138 directly toward the device 105 such that it fits within the headphone port of the device 105 when the case 100 is assembled and the device is installed therein. The other end of the extension 165 is a flexible cable that extends external to the case and provides a female adapter 167 for receiving a headphone jack. In this manner, the headphone port on the device 105 is protected and sealed off. The extension external to the case has a groove that it is pressed into along the outside of the top wall 138 when the phone port is not in use. The groove is fashioned such that the open end of the extension is sealed against a guard surface 168 formed in the top wall 138 to ensure no moisture gets through to the device 105.

FIGS. 4 and 5 show the open, receiving sides of the top and bottom shells, respectively. As shown, the protrusion 112 of the top shell runs along the side wall, extending outward. The downward extension 109 shown in FIG. 3's cross section is actually extending upward here because the top shell 110 has been inverted to show its inside. Joining seal 153 runs the perimeter of the top shell to press fit into pocket 124 of the lower shell of FIG. 5. Perimeter seal 155 also runs the perimeter of the top shell, but along the underside of the protective rim 113, so as to seat against the mobile device 105 (not shown). The protrusion 122 of the lower shell 120 is also shown extending out from along a side so as to mate with protrusion 112. In hidden lines, the twist lock assembly 180 is shown. It is hidden here because it extends from the other side of the bottom shell, in the illustrated embodiment.

As shown in FIG. 6, once the upper and lower backing elements 130 and 140 are slid together, with the protrusions 112 and 122 fit into the channels 134, 144, the backing elements are drawn together with the twist lock assembly 180. The punchouts 139, 149 in the backing elements come together to form a hole along the back of the case through which the twist lock assembly 180 extends. In the illustrated embodiment, this hole is roughly centered in the back of case 100, but it will be understood that the location of the hole could be toward top wall 138, the bottom wall 148, or offset to either side, depending on the dimensions of the backing elements, and where the parting line is to be between them. The twist lock assembly 180 may take different forms. As shown in FIG. 6, it is a circular locking mechanism that fits into the hole formed by the punchouts 139, 149. The assembly provides a groove 181 that is used to rotate the twist lock and pull the backing elements together. In certain embodiments, this is assisted by screw ridges formed in the edges of the punchouts (not shown). FIG. 6A shows the case 100 with the twist lock 180 locked such that the case is sealed and the backing elements are pulled together.

Elements of the twist lock assembly 180 are fashioned into and extend outward from the bottom shell 120. As shown in FIG. 8, the twist lock assembly comprises a round plate 185 with two opposing tracks 183 and a hollow center. Extending through the hollow center of the plate 185 is a circular raised surface 179 connected (beneath plate 185—not shown) to two stops 184. The raised surface 179 extends through the hole formed by the punchouts 139, 149 in the backing elements when assembled. The raised surface 179 comprises a central handle 182 for use in operating the twist lock assembly 180, such as via insertion of a coin. Here, the handle 182 is an open slit for receiving the coin. When the coin is turned, the raised surface 179 rotates with respect to the plate 185, causing the stops 184 to move along the tracks 183. Each stop 184 rests on a spring which allows it to be retractable. The stops are dimensioned such that their upper surfaces are flush with the back of the backing elements when the case 100 is fully assembled.

FIG. 6B shows the inside of the upper backing element 130, with side walls 134 and top wall 138 extending upward. In addition to camera hole 137, there is also a jack port 131 shown as a cutaway along the top wall 138. Though the port could be left open for direct insertion of a headphone jack 170 in some embodiments, the illustrated embodiment utilizes a jack extension assembly 165 to facilitate connection to a jack in a sealed manner. Jack extension assembly 165 is comprised of a male component 166 (internal to the case 100) and a female component 167 (external to the case 100). In certain embodiments, the extension assembly 165 is permanently affixed and sealed to the jack port 131. As the backing element 130 is slid down over the combination top shell 110/bottom shell 120, the male component 166 aligns with the jack port 161 of the top shell (see FIG. 4) and, respectively, with a port hole in the mobile device 105. In order to connect to headphone jack 170, the external female component 167 is pulled away from the jack extension guard 168 formed in the top wall 138 of the upper backing element 130 where the female component 167 is retained and environmentally sealed when not in use.

FIG. 9 shows a portion of the lower backing element 140 in an embodiment designed to cooperate with the locking assembly of FIG. 8. As shown, the backing elements in this embodiment have quarter-circle slits 151 corresponding to the tracks 183, such as that shown in FIG. 6. When the backing elements 130, 140 are slid toward one another, the stops 184 extending from the twist lock assembly 180 at the center of the bottom shell 120 are depressed against the inner surfaces of the backing elements and pop back out into the quarter slits 151 cut into the back of the backing elements once in place. The stops 184 are fixed to and aligned with the handle 182, such that they move along the tracks 183 of the twist lock assembly 180 when the handle 182 is turned. Initially parallel to the boundary between the backing elements, the handle 182 is turned ninety degrees clockwise, causing the stops 184 (now extending through the quarter-circle slits 151 in the backing elements) to pull the backing elements together. It may be advantageous to have backing seals 152 along the meeting edges of the backing elements 130, 140, which may be compressed together by the twist locking action, thereby forming a tight seal.

As a final optional step, a strap assembly 190 may be installed for user convenience. With reference to FIG. 6A, the strap assembly comprises a short portion 191, a long portion 192, and a joining clasp 194. The joining clasp 194 is permanently fixed to a second end of the short portion 192. Each of the short and long portions 191, 192 have retaining material 195 (e.g., Velcro) on a first end (not shown) that is designed to fit through one of the slits 136, 146 in one of the backing elements 130, 140 so as to come into contact with the retaining material 135, 145 on the insides thereof. It may be easier to connect these first ends to the insides of the backing elements and feed them through the slits 136, 146 from the inside out prior to assembly of the backing elements over the bottom shell 120. With the backing elements installed and locked together, and the second ends of the short and long portions 191, 192 extending through the backs of the backing elements, the second end of the long portion is fed through the clasp and sealed back against itself against external retaining material 196. As shown in FIG. 6A, the external retaining material 196 and length of the longer strap 192 may allow for adjustability of the strap 190.

FIG. 10 shows an exploded view of a top shell 210 and bottom shell 220 of a second embodiment of the device case, identified as case 200 (see FIG. 14.) This case functions in the same manner as case 100 in that it is comprised of a top and bottom shell that come together along a sealed boundary to form an outward protrusion that is then used as a track to slide upper and lower backing elements together to retain the shells together. However, in this case, only the upper shell 210 has an outward protrusion (see element 212 of FIG. 11), which aligns with an outer wall 222 of the lower shell 220. As with case 100, the top shell 210 of case 200 has a top edge 214, a bottom edge 215, and sides 216 and 217. It also has a downward extension 209, ending in a joining seal 253 that circles the perimeter of the shell and seats inside a channel formed in the bottom shell 220. The channel is formed between the inner wall 221 and the outer wall 222 of the bottom shell 220. Protrusion 212 comes to rest on the top of the outer wall 222, as shown in the cross section view of FIG. 11. Extending outward from the downward edge 209 along the perimeter of the top shell 210 are lightning port cover 211 and controls overmold 218. As will be seen, the controls overmold 218 serves the additional function of helping retain the upper and lower backing elements 230 and 240 together.

Bottom shell 220 similarly has a top edge 228, bottom edge 229 and sides 227 forming its perimeter. Around the perimeter, it features inner wall 221 and outer wall 222, the latter of which has cutouts at certain intervals to accommodate the overmolds and covers (e.g., 211 and 218) of the top shell 210. The inner wall 221 and outer wall 222 cooperate to form a trench that extends along the inner perimeter of the bottom shell 220 and accommodates the joining seal 253. Though shown as being fixed to the distal end of the downward extension 209 of the upper shell 210, it will be understood that the joining seal 253 could alternatively be molded into the trench, such that it remains with the bottom shell 220 when the top shell 210 is pulled away.

FIGS. 11 and 11A show cross-sections taken along the upper portion of a fully assembled case 200 (not shown), mirroring the location where the section of FIG. 3 is taken for case 100. However, the top shell 210 varies slightly between FIG. 11 and FIG. 11A. The case 200 of FIG. 11 features a perimeter seal 255 much like that of case 100 shown in FIG. 3. The perimeter seal seats around the perimeter of the interactive screen of device 105, and is pressed down by the hard plastic component of top shell 210 being pulled down against it by the backing element 230 compressing the top shell 210 and bottom shell 220 together. This results in a raised protective rim, such as is found in some form or another in nearly every device case on the market.

The top shell 210 of FIG. 11A departs from this in that there is no protective rim. The top surface of the case, when fully assembled, is completely flush, and takes on the same shape as the device 105 which it protects. Here, the case 200 includes a membrane 208, which expands across the top surface of the device when the case is fully assembled with device 105 installed. The membrane is translucent, and configured to allow touch-screen operability and interaction with the device. For example, the membrane might be made of materials such as Corning Gorilla Glass®. The membrane 208 seats on a shelf 207 formed around the top of the top shelf, and may be fixed there via a variety of known means, such as adhesives, and/or an interference fit with the portion of the top shell 210 extending above the shelf 207. The mating edges of top shell 210 and upper backing element 230 (and lower backing element 240—not shown) also changes slightly between the cases of FIGS. 11 and 11A.

FIG. 12 shows the inside surface of a top shell 210 equipped with a membrane 208, such as that shown in section view of FIG. 11A. As can be seen, the device 105 is seated in this shell prior to the bottom shell 220 being placed over it. With these assembled, the backing elements are slid over the protrusion formed by 212 and the outer wall 222 of the bottom shell 210. FIG. 13 shows the upper backing element 230 and lower backing element 240 pressed together along their joining interface. Each backing element features upstanding side walls 134/144 respectively. The lower backing element 240 has an upstanding bottom wall 248, while the upper backing element 230 has an upstanding top wall 238. Each of the upstanding walls comprise a portion of lip 250 that runs around the perimeter of the combined backing elements and extends over the top of protrusion 212 of the top shell 210 in order to pull the top and bottom shells together and retain them in a sealed position.

Finally, as shown in FIG. 14, once the top shell and bottom shell are assembled around the device 105, the upper and lower backing elements 230 and 240 are slid over the sides 217/227 of the assembled shells to held them together. In this illustrated embodiment, there is no twist lock assembly or separate retaining device. Rather, the backing elements are pressed over the control overmold 218. The overmold is ideally made of a pliable, resilient material that helps retain the backing elements when the cutout 258 is pressed over it.

FIG. 1A shows a third embodiment of the present invention that varies in slight ways from the first two embodiments. Notably, case 300 still adheres to the concept of securing top and bottom clam shells together using slide-over backing elements. In FIG. 1A is shown a mobile device 305 that is to be fit between a top shell 310 and a bottom shell 320. The top shell has a translucent membrane 308, such that the mobile device 305 will be completely enclosed. However, shells 310 and 320 have no clasping mechanism on them such that they will not remain together around the device on their own. Instead, upper backing element 330 and lower backing element 340 are slid over a protrusion 312 formed in the frame of the top shell. Like that of case 100 (See FIG. 6), case 300 comprises a lock assembly 380 that is used to draw the backing elements 330 and 340 together so as to fully secure the mobile device 305. Once fully installed, the mobile device 305 cannot be removed without unlocking the lock assembly 380. This may or may not require a tool, depending on the particular embodiment.

FIG. 1B shows a fully assembled case 300 without a mobile device 305 installed. In this particular example, the case 300 is configured to support an iPhone 5S. However, it will be understood that the principles and constructions taught could simply be repositioned so as to accommodate other mobile device designs. As shown in FIG. 1B, the top shell 310 includes a controls overmold 318 similar to that of case 200 (See FIG. 214). However, as will be seen, the upper backing element 330 does not extend around it along the top side. Looking through the membrane 308 of the top shell 310, the inside surface of bottom shell 320 is visible. In this case, a pattern has been formed into a pliable bottom shell insert 322, discussed further below. Also visible through the membrane are the flash buffer 324 and camera buffer 325 that are components of the bottom shell and used to protect lighting around the camera flash from the mobile device 305.

At the bottom end of the case 300 is a power cable door 358 formed in the lower backing element 340. This door opens to allow connection of a charging cable, but closes so as to seal off the power port as well as the speaker and microphone as discussed below. Also shown in a separate sensor pad 311 fitted into the top shell to align with the fingerprint sensor of the iPhone 5S. Unlike the membrane 308, which is, for example, a rigid glass, the sensor pad 311 allows for the characteristics of a user's fingerprint to be translated through to the mobile device 305 to unlock access to the device while still secured within the case 300. The sensor pad 311 is ideally positioned beneath the membrane 308 to which it is mounted, such that the pad 311 is flush with the Touch ID home button of the mobile device 305 in its resting state. The pad 311 is bonded by an adhesive or ultrasonic welding to the membrane seal, which is, in turn, fixed to the inner surface of the top shell 310. In this manner, the pad 311 functions to convey fingerprints to the device, but the case 300 is still watertight in the area.

FIG. 4A shows the inside of top shell 310, which forms a cradle into which the mobile device is placed, with its view screen down toward membrane 308. The membrane 308 has an ear port 307 with a water-proof seal placed over it to allow sound to pass (i.e., when someone is listening to the device as in a phone conversation) but not water. As with prior embodiments discussed, the top shell 310 has a top wall 314, a bottom wall 315, and opposing side walls 316 and 317. Protrusion 312 extends outward from at least each side wall 316 and 317 for purposes of helping seal the case 300. The protrusion also forms a shelf for the outer wall 323 of the lower shell 320, as shown best in FIG. 11B.

Along side wall 317 is the controls overmold 318, which features up and down volume overmolds 318A and 318B, as well as a toggle switch 319 for use in operating a mute selection on the mobile device 305 when it is installed in the case 300. Moving around the top wall 314, there is a sleep control seal 363 that allows sleep button 364 to be operated while preventing the ingress of liquids. Opposite that are three holes in the bottom wall 315: microphone port 367, speaker port 368 and power port 369. These ports are always open and are not sealed by the top shell itself. Rather, they are sealed from outside liquids by the power cable door 358 of the lower backing element 340. Again, it will be understood that these ports are configured for a particular mobile device 305, but could be located elsewhere along the perimeter of the case 300 as needed to accommodate other designs.

FIG. 4B provides an exploded view of the top shell 310 shown in FIG. 4A, but showing the outer or top surface. As shown, the top shell 310 includes a perimeter frame 313, which is preferably of a rigid material. The protrusion 312 is a rigid surface feature of the frame 313 and extends at least along the side walls 316 and 317. Controls overmold 318 is of a flexible or semi-flexible material such as a polymer that provides a watertight seal in the perimeter openings through which the controls 318A, 318B and 319 operate to contact corresponding controls on the device 305. In this same manner, sleep control seal 363 is flexible and covers around the sleep button 364. Foam seals 365 cover over the speaker and microphone ports through the bottom wall 315 of the top shell frame 313. Below the top shell frame 313 are the membrane seal 309, the membrane 308, and the sensor pad 311. Once assembled during manufacture, the components shown on FIG. 4B are generally intended to stay together as one single component—the top shell 310.

FIG. 5A shows an isometric rear view of the bottom shell 320. Like the top shell 310, the bottom shell 320 is preferably of a rigid construction, though it has components that are not rigid. From the rear or outer side of the bottom shell 320, primarily the bottom shell frame 321 is all that is visible. The frame 321 has sidewalls, a top wall and bottom wall in the illustrated embodiment, but the walls are shorter than those of the top shell 310. That is why insertion of the mobile device 305 is performed by placing the device face first into the top shell and then placing the bottom shell 320 over the backside of the device before sliding the backing elements on. In the illustrated embodiment the side wall in view has a controls cutaway to provide room for the controls overmold 318 of the top shell 310. It will be understood that this geometry could be reversed such that the controls overmold is part of the bottom shell 320 and the bottom shell 320 has the higher walls instead of the top shell 310 without departing from the spirit of the invention. At the top left corner of the outer surface of the bottom shell 320 is shown a camera hole 327. This hole supports the camera seal assembly 326, which is more clearly illustrated in FIG. 5B.

FIG. 5B is an exploded view of the bottom shell 320 taken from the other side (the inner side) of the shell. At bottom is the shell frame 321 with its camera hole 327. Above that is a bottom shell lining 322. While the frame 321 is rigid, the lining 322 is flexible or semi-flexible and may be molded into a pattern such as that shown. The pattern may have some depth such that it forms ribs 350 for cushioning the back of the mobile device 305. These ribs may be few or many, large or small, but ideally should only rise just slightly (perhaps a millimeter) off of the inner surface of the lining 322. The lining 322 generally is of the same shape as the frame 321, but slightly smaller so as to fit on its inside. In the exemplary embodiment, the lining is permanently co-molded or over-molded to the frame such that they form a single, inseparable component. The lining 322 also has a camera hole 327, which joins to the hole in the frame to support the seal assembly 326 and the flash buffer 324 and camera buffer 325. These buffers help control light distribution while the seals help to prevent water ingress.

FIG. 7 shows a rear view of the fully assembled case 300, but primarily serves to illustrate the rear of the backing elements 330 and 340 now installed. As indicated, the outer perimeter of the backing elements 330 and 340 are guarded by upper backing bumper 333 and lower backing bumper 343, respectively. While the upper and lower backing frames 331 and 341 (see FIG. 7B) are ideally of a rigid plastic or metal, the bumpers are flexible and assist in cushioning impact. Power cable door 358 is shown in the closed position at the bottom of the lower backing element 340. Camera hole 337 (which aligns with camera hole 327 in the bottom shell 320) is shown in the upper left corner of the upper backing element 330. Controls 319, 318A and 318B appear along the right side, where the perimeter of the upper backing element 330 is trimmed away to allow space for them. Certain components of the lock assembly 380 are visible in this view. Specifically, lock wheel 381, with its cam hole 386, are present as well as the position indicator hole 385, which serves to identify to the user whether the backing elements have been secured together or not. The case 300 may also include a key or tool (not shown) for insertion into the cam hole 386 for use in turning lock wheel 381.

FIG. 7A shows the upper and lower backing elements 330 and 340 from the other side (exposing their inner surfaces). While the elements are shown locked together for purposes of explanation, this would typically not be done unless the backing elements were first slid over the sub-assembled top and bottom shells 310/320, which would in turn contain the mobile device 305. Generally, the backing elements form an outer perimeter of the case 300, with breaks or holes corresponding to the control features of the mobile device 305 it is configured for use with—in this case, an iPhone 5S. This includes control port 362, camera hole 337 and the break for the control overmold 318 (not shown here) which extends through the side wall of the upper backing element 330. In this view, the power cable door 358 is shown in the open position, thus allowing access to charge the mobile device 305. When closed, this door provides a watertight seal around the opening otherwise formed in the bottom wall of the lower backing element 340. The door 358 is held closed, at least in part, but the seal plugs 344, which are inserted into corresponding openings in the top shell 310 (e.g., the speaker port 367 and microphone port 368 of FIG. 4A). In this view, the inner surface of the lock assembly 380 is plainly in view showing that the lock wheel 381 on the outer side has been turned so as to draw the backing elements together. This would normally not be visible because it would be occluded by the bottom shell 320.

FIG. 7B shows an exploded view of both backing elements 330 and 340 from a rear isometric angle. As shown, the lower backing element 340 comprises a backing frame 341, which is typically a single, rigid molded plastic, side bumpers 343 and back pad 342. Just as the bumpers extend out to protect impacts from the sides, the back pad (also a flexible or semi-flexible polymer, typically) extends slightly beyond frame 341. It also covers over the lock wheel housing 382 formed partially in the lower backing element 340. The lower backing element also comprises components of the power access door 358, including the pin 359 on which it rotates as well as water and acoustic seals 361 and 360 that fit around or over the plugs 344.

The upper backing element 330 comprises a similar rigid, typically plastic molded frame 331 with depressions to receive bumper 333 along its perimeter and back pad 332 along its outer (rear) surface for impact absorption. Back pad 332, which is flexible or semi-flexible, has a cutout to keep the camera hole 337 uncovered, as well as a lock access hole 383 through which the lock wheel extends and the position indicator hole 385. The pad 332 covers over the remainder of the lock wheel housing 382 that is formed in the rear surface of the upper backing element. When assembled, the lock wheel 381 is placed in the lock wheel housing 382 such that the cam hole 386 is accessible from the outside of the back pad 332. The lock wheel assembly 380 has two positions (open and closed) corresponding with the two detents 384. In the open position, a first detent will appear through the position indicator hole 385. In the closed position, the second detent will so appear. The detents may be color coded, for example, with green indicating closed and red indicating opened. In other embodiments, there may be two position indicator holes 385A and 385B positioned such that, in a closed position, the lock wheel 381 positions a color patch under hole 385A and, in an open position, the lock wheel 381 positions a color patch under hole 385B. These cameral holes might be formed in the shape of a closed and open padlock, for instance, respectively. Finally, camera trim insert 338 fits around the camera hole 337 to help control lighting for the camera feature of the mobile device 305.

FIG. 11B shows a cross section taken through a side wall of the case 300 as shown in FIG. 7. This cross section illustrates the similarities and differences with case 200 (FIGS. 11 and 11A) and case 100 (FIG. 3). First, each case features a top shell (110, 210, 310) with a perimeter wall around the outside of a mobile device (105, 205, 305), where the wall features a downward extension (109, 210, 304) that fits at least partially into a trench formed by the perimeter of the bottom shell (120, 220, 320). In each case, the top shell features an outward protrusion (112, 212, 312) along its perimeter wall that abuts an outer portion of the bottom shell. In each case, the upper backing element (130, 230, 330) forms a housing that extends around the exterior of the bottom shell and at least a portion of the top shell to grip around the protrusion (112, 212, 312) to hold the top shell and bottom shell together.

After acknowledging those similarities, there are some differences. Like the section of FIG. 11A (case 200), FIG. 11B (case 300) includes a membrane (208, 308). In FIG. 11B, the membrane 308 is attached to the perimeter of the top shell 310 by the adhesive membrane seal 309. But it also has a raised perimeter like the sections in FIG. 11 and FIG. 3 (case 100), which does not exist in FIG. 11A. Cases 100 and 200 each feature at least a joining seal (153, 253) that is compressed when the top shell downward extension fits into the channel formed by the bottom shell. Case 300 uses no such seal. Rather, the bottom shell comprises a compressible lining 322 that forms an interior surface of both the channel and the entire bottom shell 320. Case 300 has bumpers (333) and back pads (332) to soften impact. While these could be added to cases 100 and 200, case 200 has none as shown in FIGS. 11 and 11A, and case 100 only has the side bumpers (133) as shown in FIG. 3.

FIG. 15 and FIG. 16 illustrate a case 400 for securing over a mobile device 405 according to a fourth embodiment. It will be understood that the components, and the dimensions and shape, of case 400 could be modified to fit different types of mobile devices without departing from the novelty of the case 400 described herein. FIG. 15 illustrates an exploded view of case 400. FIG. 16 shows a side view of case 400 when case 400 is fully assembled around mobile device 405.

As illustrated in FIG. 15 and FIG. 16, case 400 is comprised of four principle parts: an upper backing element 430, a lower backing element 440, a top shell 410, and a bottom shell 420. Generally, the upper backing element 430 and the lower backing element 440 come together around the perimeter of mobile device 405 to at least partially enclose mobile device 405 so that at least a display screen of mobile device 405 is exposed. According to some embodiments, a display screen of mobile device 405 may be covered by a transparent membrane 408 (see FIG. 17). Top shell 410 and bottom shell 420 have no clasping mechanism on them such that they will not remain together around mobile device 405 on their own. Instead, lock assembly 480 is provided to secure components of case 400, including the top shell 410 and bottom shell 420, around mobile device 405. Lock assembly 480 is a wheel type locking assembly that is rotated into track 483 to draw upper backing element 430 and lower backing element 440 together to secure mobile device 405 within case 400. Once fully installed around mobile device 405, upper backing element 430 and lower backing element 440 are configured to secure top shell 410 and bottom shell 420 into their positions around mobile device 405.

FIG. 15 further illustrates top shell 410 including a toggle switch member 419. Toggle switch member 419 is configured to allow a user to engage a toggle switch (not illustrated) on mobile device 405. Toggle switch member 419 engages (i.e., contacts) the toggle switch on mobile device 405 to flip the toggle switch on mobile device 405 from a first position (e.g., up position) to a second position (e.g., down position), and vice versa.

An outer perimeter of upper backing element 430 may be protected by an upper backing bumper 433 as illustrated in FIG. 15. Upper backing element 430 may further include a camera hole 437 to allow a camera lens of mobile device 405 to be accessible for taking pictures or videos. An outer perimeter of lower backing element 440 may be protected by a lower backing bumper 443 as illustrated in FIG. 15. Lower backing element 440 may further include a pass-through accessory hole 499 that allows an accessory piece to be looped or clasped through and attached to the case, such as by way of a lanyard (not shown). FIG. 16 illustrates accessory hole 499 as extending completely through lower backing element 440. Backpad 442 may further be attached to lower backing element 440 to provide additional protection for case 400.

Lower backing element 440 may further include a volume up overmold 418A and a volume down overmold 418B as illustrated in FIG. 15. Volume up overmold 418A is configured to overlap with secondary toggle switch member 4191 in an assembled configuration of case 400, and volume down overmold 418B is configured to overlap with secondary toggle switch member 4192 in an assembled configuration of case 400. As illustrated in FIG. 15, the secondary toggle switch members 4191/4192 are molded to the top shell 410, while the volume overmolds 418A/418B are molded to the lower backing element. Volume up overmold 418A and secondary toggle switch member 4192 are configured to overlap with a volume up bottom 406 on the mobile device 405 (e.g., illustrated in FIG. 17), while volume down overmold 418B and secondary toggle switch member 4192 would overlap with a volume down button on the device (not shown), when case 400 is in the assembled configuration.

FIG. 17 illustrates a section view of a side edge of case 400 taken through section 17-17 from FIG. 16 that goes though volume up overmold 418A. Bottom shell 420 includes volume up overmold 418A to allow a user to engage a volume up button 406 on mobile device 405. To engage (i.e., contact) the volume up button 406 of mobile device 405, volume up overmold 418A may be pressed in by a user. When volume up overmold 418A is pressed in, the movement of volume up overmold 418A may translate to engage secondary toggle switch member 4191 such that secondary toggle switch member 4191 contacts the volume up button 406 of the mobile device 405. In this way, a user applying pressure to volume up overmold 418A may move volume up overmold 418A towards mobile device 405 and translate this movement through secondary toggle switch member 4191 to engage and activate volume up button 406 of mobile device 405. According to some embodiments, volume up overmold 418A may be configured to engage toggle switch 406 directly without the inclusion of secondary toggle switch member 4191. Spacing 4100 may surround portions of volume up overmold 418A and secondary toggle switch member 4191 to allow deformations of volume up overmold 418A and/or secondary toggle switch member 4191 caused by a pressure on volume up overmold 418A and/or secondary toggle switch member 4191 to occupy within spacing 4100. Also, additional spacing 4200 may be present at specified sections between bottom shell 420 and lower backing element 440 to provide for additional cushioning between the softer bottom shell 420 and the harder backing element 440. Bottom shell 420 may further include a bottom shell cushion 421 in direct contact with mobile device 405. Transparent membrane 408 (i.e., protective screen cover) may cover a display screen of mobile device 405.

FIG. 18 illustrates an exploded view of components of lower backing element 440, including an exploded view of a door clasp assembly of case 400. The door clasp assembly is comprised of side hinges 475, body hinges 479, lifting tab 460, first hinge pin 461, second hinge pin 462, seal assembly 465 (which may include various dust and fluid seals as well as fittings, etc.), and door 458. As described further below, door 458 rotates about the first hinge pin 461 to provide access to an inner chamber 470 where ports of the mobile device 405 can be accessed, such as by temporary wired connections to provide power to a power port or receive audio signals from an audio port. When door 458 is open, water, dust and other materials may enter inner chamber 470. However, when door 458 is fully sealed, inner chamber 470 is also sealed from dust, dirt and water, while sound may still permeate through sealing assembly 465. This allows for voice communication with the mobile device (receiver for input) and audio output (such as speaker phone or playing music) when the door 458 is sealed. This is facilitated by one or more openings 456 in the door. The openings are in the hard material of door 458, but sound can still pass through the sealing assembly 465 to reach the inner chamber 470 where the speaker and receiver can be accessed. Although sealing assembly 465 is shown to be comprised of four components, sealing assembly 465 may be comprised of one or more components according to other embodiments.

The lifting tab 460 (or “rocker assembly”) is used to unlatch the door 458 as explained below. The tab 460 has several extensions, each containing a top pin opening and a bottom pin opening, as best shown in FIG. 18. When fully assembled, first hinge pin 461 is configured to secure door 458 to lifting tab 460 by inserting first hinge pin 461 through a number of top pin openings of lifting tab 460, first door hinge 458A, and second door hinge 458B. In this way, door 458 will be securely attached to lifting tab 460 and rotate about first hinge pin 461. When fully assembled, second hinge pin 462 is inserted through a number of bottom pin openings of lifting tab 460 and secured to lower backing element 440 through side hinges 475 and body hinge 479. In this way, lifting tab 460 will be secured to lower backing element 440 and rotate about second hinge pin 462. Backpad 442 may include a cutout 445 to allow access to lock assembly 480.

FIG. 19 illustrates the doorclasp assembly in a locked (sealed/closed) configuration. In the locked configuration, door 458 is closed against lower backing element 440, thus positioning the sealing assembly 465 within the inner chamber 470. While in the locked configuration lifting tab 460 is laid down substantially flat against the lower backing element 440 and nestled into a carve out provided by lifting space 473. This carve out in the backpad 442 enables a user to get underneath a portion of lifting tab 460. By getting underneath lifting tab 460, a user may lift the lifting tab 460 up to release lifting tab 460 from its locked configuration, and into the configuration shown in FIG. 19A. In FIG. 19A, lifting tab 460 is shown to be released from its locked configuration and transitioned into a semi-opened configuration. Lifting tab 460 rotates with respect to lower backing element 440 about second hinge pin 462 to rotate to the semi-opened configuration illustrated in FIG. 19A.

In the semi-opened configuration illustrated in FIG. 19A, door 458 is also released from its locked configuration and is partially opened as illustrated by door 458 no longer being closed against lower backing element 440. However, the door clasping member 454 forming the distal edge of the door from the hinges 458A and 458B is still clasped (see, e.g., FIG. 21 and discussion below). The spacing created between door 458 and lower backing element 440 in the semi-opened configuration illustrated in FIG. 19A, enables door 458 to then be pressed down to release the door clasping member 454 from the lower clasping member 444 of the lower backing element 440, and rotate about first hinge pin 461 to transition to a fully-opened configuration illustrated in FIG. 19B.

In the fully-opened position illustrated in FIG. 19B, door 458 is rotated up about the first hinge pin 461 to allow unfettered access to inner chamber 470. As shown best in FIG. 21, inner chamber 470 is defined by portions of mobile device 405, top shell 410, bottom shell 420, and door 458 (when closed as illustrated in FIG. 21). By allowing access to inner chamber 470 in the fully-opened configuration, one or more ports on a lower portion of mobile device 405 that were previously secured behind door 458 in the locked configuration may be accessed. When door 458 is rotated to the fully-opened configuration, lifting tab 460 is rotated back towards lower backing element 440 to be substantially flat with lower backing element 440.

As shown in FIGS. 19-19B, the door securement mechanism disclosed provides a door with not simply an open and shut condition, but with a sealed condition (FIG. 19). The action provided by the geometry of the lifting tab 460, the double-hinge pin architecture, and the overlapping lip of the clasping members 454 and 444 essentially pulls the door against the rest of the lower backing element 460 to ensure a watertight fit around the door's perimeter, which may have an o-ring or other compressible material to facilitate a good seal.

FIG. 20 illustrates a bottom view of case 400. FIG. 21 illustrates a section of lower backing elements and the doorclasp assembly taken through section 21-21 from FIG. 20. The doorclasp assembly of case 400 is shown to be in the locked configuration in FIG. 21. Lower backing element 440 is shown to include a lower clasping member 444, and door 458 is shown to include door clasping member 454. Door clasping member 454 is configured to engage with lower clasping member 444 to secure door 458 to lower backing element 440 in the locked configuration. Inner chamber 470 is shown to include additional spacing 4000 between components of the doorclasp assembly and the mobile device 405. FIG. 21 also illustrates an exemplary port 407 of mobile device 405 that may be accessed when door 458 is in the fully-opened configuration. For example, given the central positioning of the section, port 407 would correspond with the “lighting port” or power receiving receptacle on APPLE's iPhone 5 model smart phone.

It will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the novel and non-obvious techniques disclosed in this application. For example, a single backing element running the length of the top and bottom shells might be substituted, such that it could slide along the entire length of the outward protrusion formed by the mating edges of the top and bottom shells. Moreover, the dimensions of the protrusions and the shapes of both the top and bottom shells could be different than shown in the illustrated embodiments without departing from the concepts claimed below and enabled herein. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the novel techniques without departing from its scope. Therefore, it is intended that the novel techniques not be limited to the particular techniques disclosed, but that they will include all techniques falling within the scope of the appended claims. It is noted that each of the embodiments illustrated in the figures and discussed herein are of the variety including top and bottom clam shells that are placed together around a mobile device and sealed together by backing elements that slide together over the exterior sides of the clam shells. 

What is claimed is:
 1. A door securement system for an encasement comprising: an encasement body providing a cavity for housing an electronic device, the cavity including an opening at one end configured to enable acceptance of a temporary wired electrical connection; a lifting tab rotatably coupled to the encasement body via a second hinge pin, the lifting tab configured to transition from a locked configuration to an open configuration; and a door rotatably coupled to the lifting tab via a first hinge pin that passes through at least a first door hinge of the door and a first set of extensions of the lifting tab, the door configured to seal the opening from water egress in the locked configuration and to enable access to the opening in the open configuration.
 2. The door securement system of claim 1, wherein the first set of extensions of the lifting tab has a first set of through holes along a first axis for receiving the first hinge pin, and wherein the lifting tab further comprises a second set of extensions having a second set of through holes along a second axis for receiving the second hinge pin.
 3. The door securement system of claim 2, wherein the door is rotatably coupled to the lifting tab by the first hinge pin, which extends through the first set of through holes; and wherein the lifting tab is rotatably coupled to the encasement body by the second hinge pin, which extends through the second set of through holes and through an encasement body hinge.
 4. The door securement system of claim 2, wherein the first axis and the second axis are parallel to one another.
 5. The door securement system of claim 1, wherein the lifting tab is configured to lay flat with a surface of the encasement body while in the locked configuration.
 6. The door securement system of claim 1 having a semi-open configuration, wherein the lifting tab is rotated away from a surface of the encasement body, and wherein the door is rotated to a position in which water access to the inner chamber is allowed, but a door clasping member is still attached to the encasement body.
 7. The door securement system of claim 6, wherein rotating the lifting tab causes the door to rotate to the semi-open configuration.
 8. The door securement system of claim 1, wherein the door comprises: a door clasping member configured to engage with an encasement clasping member along a border of the door distal from the first hinge pin.
 9. The door securement system of claim 1, wherein an inner chamber is defined by at least the door and the encasement body when the door is in the locked configuration.
 10. The door securement system of claim 1, wherein a sound-permeable sealing assembly is positioned within the inner chamber by the door when the door is in the locked configuration.
 11. A door securement system for an encasement comprising: an encasement body providing a cavity for housing an electronic device, the cavity having an opening at one end to allow for temporary wired electrical connection to a remote input or output; a door for sealing the opening when the wired electrical connection is absent; a rocker assembly for rotatably connecting the door to the encasement body, the rocking assembly comprising: a series of extensions, each extension having a proximate through hole and a distal through hole; a first hinge pin extending along a first axis and passing through each proximate through hole and through an encasement body hinge; and a second hinge pin extending along a second axis to pass through each distal through hole and through a door hinge extending from the door such that the rocker assembly and the door are directly connected when the door securement system is in either of an open or a closed position.
 12. The door securement system of claim 11, wherein the first axis and the second axis are parallel to one another.
 13. The door securement system of claim 12, wherein the rocker assembly releases or secures the door from the closed position by rotating the first hinge pin at least partially around the second hinge pin.
 14. The door securement system of claim 11, wherein the door comprises: a lower edge from which the door hinge bracket extends; and an upper edge from which a sealing lip extends; wherein the sealing lip presses over a retaining lip of the encasement body to seal the door in the closed position.
 15. The door securement system of claim 11, wherein, when the door is in the closed position, the cavity is waterproof.
 16. A door securement system for an encasement comprising: an encasement body providing a cavity for housing an electronic device, the cavity having an opening at one end, and the encasement body forming a first clasping lip adjacent to a first side of the opening; a lifting tab having a first hinge pin rotatably connecting the lifting tab to the encasement body adjacent to a second side of the opening; and a sealing door configured to span the opening, the sealing door having a first perimeter side rotatably connected to the lifting tab by a second hinge pin that passes through at least a first door hinge of the sealing door and a first set of extensions of the lifting tab, and a second perimeter side comprising a second clasping lip configured to overlap the first clasping lip to connect the sealing door to the encasement body.
 17. The door securement system of claim 16, wherein the first hinge pin is parallel to the second hinge pin.
 18. The door securement system of claim 16, wherein the system is configurable in: a first configuration in which the first clasping lip is separated from the second clasping lip, and the second perimeter side of the door is rotated away from the first side of the opening to allow wired access to a charging port on an electronic device housed within the cavity of the encasement body; a second configuration in which the first clasping lip overlaps the second clasping lip, and the lifting tab is rotated away from the encasement body such that the first perimeter side of the door is separated from the second side of the opening; and a third configuration in which the first clasping lip overlaps the second clasping lip and the lifting tab is rotated substantially flush with the encasement body such that the first perimeter side of the door is sealed against the second side of the opening.
 19. The door securement system of claim 18, wherein the door further comprises at least one through hole covered by a sound-permeable seal assembly that allows sound to enter and exit the cavity when the door securement system is in the third configuration.
 20. The door securement system of claim 16, wherein the door further comprises at least one through hole covered by a sound-permeable seal assembly. 